User Interface and Content Translation System

ABSTRACT

A system solution offers a Business Entity an automatically generated set of User Interfaces to run on a plurality of Client Devices of different characteristics in terms of operating system, hardware, and look and feel, and yet provide the same user experience. A User Interface that offers a user experience on a Reference Client Device is automatically translated to offer the same user experience on a plurality of Client Device having different characteristics from the Reference Client Device. The objects displayed in the User Interface for the Reference Client Device are placed on a Translation Grid that is generated and superimposed on the User Interface. A Client Translator and Generator translates the User Interface from the Reference Client to the plurality of Client Devices using the Translation Grid and a set of Translation Rules. A measurement of the automatic translation process identifies optimal and sub-optimal translation for each Client Device.

PRIORITY APPLICATION

This application is a continuation of U.S. patent application Ser. No.13/833,849, filed on Mar. 15, 2013, to be issued as U.S. Pat. No.10,075,560, the contents of which are herein incorporated by referencein its entirety.

CROSS-REFERENCE TO RELATED APPLICATIONS

The present application is related to the co-filed U.S. application Ser.No. 13/833,589 entitled “Apparatus for Single Workflow forMulti-Platform Mobile Application Creation and Delivery”, Ser. No.13/833,669 entitled “Method for Single Workflow for Multi-PlatformMobile Application Creation and Delivery”, Ser. No. 13/833,775 entitled“Dynamic User Interface Delivery System”, and Ser. No. 13/834,765entitled “Hierarchical Application Client System”, which are assigned tothe same assignee as the present application and invented by the sameinventors as the present application and incorporated herein byreference in their entireties.

BACKGROUND OF THE INVENTION

The internet is a communication system that interconnects the world. Theinternet has been structured to provide connectivity to billions ofusers with laptops, notebooks, desktops, Internet Enabled TV sets,cellular phones, smartphones like the iPhone™, Android™ and Blackberry™,wearable devices, and tablets. The internet 1-3 connects a Client Device1-2 to a server 1-4 and the server to the same Client Device asillustrated in 1-1 of FIG. 1A or to another Client Device (notillustrated). The Client Device 1-2 can have at least one display screen1-8 that can be a touch sensitive screen, pen based or both. The screencan display various icons or be attached to a physical keypad 1-9. Asillustrated in 1-1, the Client Devices are physical and can be eithermobile, such as cellular phones, smartphones, wearable devices, andtablets, or non-mobile, such as laptops, desktops, and TV sets, TheClient Devices 1-2 are coupled to the internet by wired (a physicalinterconnect), wirelessly (waves through space), or both wired/wirelessnetworks. The wireless connectivity can be cellular (3G, 4G, etc.),Wi-Fi, Bluetooth, WiMax, etc. The Client Device 1-2 runs the ApplicationClient which is the actual application software running on device.

FIG. 1A also shows an application store connected to the Internet. Theapplication store makes application clients available for download tothe Client Devices. There is a plurality of application stores, each ofthe application stores dedicated to make available for downloadApplication Clients for a certain type of Client Device or Client Deviceoperating system. For example, the Apple™ application store makesApplication Clients for the iPhone™ and iPad™ available for download,the Android™ application store makes Application Clients for smartphonesand tablets running the Android™ operating system available fordownload, etc. There are application stores dedicated to support mobileClient Devices (for example, the iPhone™/iPad™ Apple™ application store,the Blackberry™ application store, etc.), and application storesdedicated to support non-mobile Client Devices (for example, the Mac™Apple™ application store, which makes applications for Apple™ computersrunning the Mac™ operating system available for download).

The Cloud uses the network of the internet to offer services to users byusing a combination of hardware and software embedded in the network. AnApplication Client can be in the Cloud, but in this case the ClientDevice is a “virtual” Client Device. The “virtual” Client Device has away to provide access to the Application Client running in the cloud viaa physical Client Device. For example, as in the example listed in 1-5of FIG. 1B, a web browser 1-6 running on the physical Client Device 1-2and coupled to the client/server 1-7 in the Cloud via the Internetaccesses the Application Client running in the Cloud, which performs theactual application software. For the Cloud, there are two cases: theentire Application Client runs in the Cloud, or a small portion of theApplication Client runs on a physical Client Device while most of thelogic runs in the Cloud.

FIG. 2A illustrates a system 2-1 with the hardware 2-16 and software2-15 of a Client Device 1-2. The Client Device 1-2 is coupled to theinternet 1-3 via wireline connection or Radio Frequency (RF) wirelesstransmission network (wired/wireless) 2-2 and further coupled to a bankof servers 2-4 via a second interconnection 2-3 that can be wired orwireless. The communication link is a receiver and a transmitter knownas a transceiver and is coupled to either a wired connector or anantenna (not illustrated) for the wireline connection or RF wirelesstransmission network, respectively. In general, these links: wired,wireless, cellular, internet, etc. are called the Communication network.The Communication network couples all components together. The server'sbank 2-4 comprises server-0 2-11 to server-N 2-12. The bank contains atleast one server and these servers can be localized, coupled by anIntranet, or be physically separated from one another, coupled by theInternet. The operating system (OS) 2-13 running in the Client Device isclosely coupled with the hardware 2-16, especially in case of MobileClient Devices 1-2. The hardware 2-16 comprises at least one processor2-5 operating under the operating system 2-13. The processor 2-5 iscoupled to at least one memory 2-7 and at least one communication link2-9 via at least one bus 2-8. At least one communication link 2-9couples the Client Device to the outside world through a wired and/orwireless interconnection via the transceiver. The Client Device offersthe user at least one mode of input and one mode of output. One mode ofinput to the Client Device 1-2 is via the touch based keypad 2-6 orthrough voice control (not illustrated). The screen 2-10 can be a touchsensitive screen and provide a second mode of input. The screen 2-10 canprovide an output response or sound can provide a second mode of outputknown as voice output (not illustrated). Other hardware components suchas MEMS, power supplies, etc. are not mentioned but as well-known bythose skilled in the art. A set of applications or Application Clients2-14 run on the Client Device are coupled to the operating system 2-13.The Client Device is one of a plurality of Client Devices coupled to theInternet. An Application Store 1-10 connected 2-21 to the Internet.

FIG. 2B illustrates that when the term server 2-20 is used, this serveris a sub-set representation of a Computer hardware 2-17, which cancontain software 2-18, a database 2-19 and the server 2-20 itself. Othercomponents not illustrated are the memory, power supply, etc. Oneskilled in the art is knowledgeable of other components contained inthis device and will not be described further. All servers used in thisspecification are substantially the same as the server 2-20.Furthermore, a plurality of servers and a plurality of databases can beembedded in the Computer hardware 2-17.

The term “Client Device” encompasses the device being mobile,non-mobile, or located in the Cloud. However, in some cases, for furtherdistinction within this document the term “Mobile Client Device” will beused for mobile devices, “Non-Mobile Client Device” will be used fornon-mobile devices and “Cloud Client Device” will be used for the deviceformed in the Cloud.

FIG. 3A and FIG. 3B present two different types of Application Clients.This distinction is especially relevant in the case of mobile ClientDevices, but is also applicable to non-mobile Client Devices. FIG. 3Ashows a Native Application Client 3-1 and how it relates to the layeredstacks of the hardware/software representation of a Client Device 1-2.The Native Application Client 3-1 includes a User Interface 3-5 and aClient Functionality 3-2. The User Interface 3-5 provides at least onemode of input and one mode of output to the end user and is the meanswith which the end user interacts with the Native Application Client3-1. The Native Application Client 3-1 is an executable which runsdirectly on the operating system 2-13 of the Client Device 1-2, which inturn runs on the hardware 2-16 of the Client Device. The operatingsystem 2-13 provides a set of system libraries 3-3, which the NativeApplication Client uses. The Native Application Client is compiled torun on the operating system of the Client Device. The Native ApplicationClient needs to be downloaded to the Client Device and installed on theClient Device in order to run on the Client Device. The User Interface3-5 depends on the operating system 2-13 and on the hardware 2-16, andin particular on the screen 2-10.

FIG. 3B shows a Non-Native Application Client and how it relates to thelayered stacks of the hardware/software representation of a ClientDevice. The Non-Native Application Client 3-1 h includes a UserInterface 3-5 h and a Client Functionality 3-2 h. The User Interface 3-5h provides at least one mode of input and one mode of output to the enduser and is the means with which the end user interacts with theNon-Native Application Client 3-1 h. The Non-Native Application Client3-1 h does not run directly on the operating system 2-13 h of the ClientDevice, but instead uses a web browser 3-5 installed on the ClientDevice in order to run. The Non-Native Application Client 3-1 h iswritten in a programming language that is understood by the web browserrunning on the Client Device. The most common example of such a languageis HTML5. The web browser running on the Client Device contains a parser3-4 that is used to interpret the code of the Non-Native ApplicationClient 3-1 h. The Non-Native Application Client 3-1 h does not depend onthe Client Device 1-2 a since it does not run directly on the operatingsystem 2-13 h but instead uses the web browser 3-3 running on the ClientDevice 1-2 a. The Non-Native Application Client 3-1 h can run on anyClient Device 1-2 a that runs a web browser 3-5 capable of understandingthe language which the Non-Native Application Client is written in. Theweb browser 3-5 may depend on the Client Device 1-2 a, but theNon-Native Application client does not depend on the Client Device. TheUser Interface 3-5 h depends on the operating system 2-13 h and on thehardware 2-16 h, and in particular on the screen 2-10 h.

The term “Application Client” refers to the portion of the applicationrunning on the Client Device. The term “Application Client” encompassesthe Application Client running on a mobile Client Device, a non-mobileClient Device or even in the Cloud. The Cloud can run a portion of theApplication Client in the server while the remaining portion of theApplication Client can run on the Client Device, simultaneously. Theterm “Application Client” is used to refer to both Native and Non-NativeApplication Client. The term “Mobile Application Client” will be usedfor both Native and Non-Native Application Clients running on a mobileClient Device, but it also applies to Client Devices that are non-mobileor in the Cloud.

An approval and download process in the Application Store is illustratedin FIG. 4. A Business Entity 4-1 creates a new application whichcomprises a new Native Application Client 3-1. The new NativeApplication Client 3-1 is submitted 4-3 to the Application Store 1-10for an approval process 4-4. Once the new Native Application Client isaccepted 4-5, information is passed to the Application Store 1-10 tomake the new Native Application Client available for download andinstall 4-6 into a Client Device 1-2. A Client Device 1-2 which desiresthe Native Application Client 3-1 downloads the Native ApplicationClient from the corresponding application store 1-10. For example, aniPhone™ downloads its desired Native Application Client from the Apple™application store, an Android™ device downloads its desired NativeApplication Client from the Android™ application store, etc. Once theNative Application Client is downloaded to the Client Device, it isinstalled on the Client Device so it can run on the operating system ofthe Client Device. The client now contains a “native” applicationcoupled to the operating system 2-13 (see FIG. 2A) of the Client Device.The Native Mobile Application Client executable depends on the operatingsystem (OS) as an iPhone would require a different executable than anAndroid™ phone.

BRIEF SUMMARY OF THE INVENTION

It is a first objective of the invention to provide a system solutionthat offers the Business Entity a way to automatically generate a set ofUser Interfaces to run on a plurality of Client Devices of differenttypes in terms of operating system, hardware, and look and feel. A firstUser Interface in the set of generated User Interfaces is adapted to thecharacteristics of a first Client Device in the plurality of ClientDevices. The first generated User Interface offers the end user on thefirst Client Device the same user experience as the user experience thata second generated User Interface in the set of generated UserInterface, which is adapted to the characteristics of a second ClientDevice in the plurality of Client Devices, offers the end user on thesecond Client Device. Using these inventive ideas, the Business Entityautomatically generates a plurality of User Interfaces that offer thesame user experience in a plurality of Client Devices of differentcharacteristics in terms of operating system, hardware, and look andfeel.

It is a second objective of the invention to provide a way to quantifythat a first User Interface offers the same user experience on a firstClient Device as a second User Interface offers on a second ClientDevice of different characteristics in terms of operating system,hardware, and look and feel.

A preferred embodiment of the invention is a method to automaticallytranslate a User Interface designed to offer a user experience on aReference Client Device into a User Interface designed to offer the sameuser experience on a first Client Device the first Client Device havingdifferent characteristics from the Reference Client Device in terms ofoperating system, hardware, and look and feel.

In this preferred embodiment of the invention, the objects displayed inthe User Interface for the Reference Client Device are classified asContent Objects, Shape Objects, and Navigation Object. A ReferenceTranslation Grid is generated and superimposed on the User Interface ofthe Reference Client Device. The objects displayed in the User Interfacefor the Reference Client Device are placed in relation to the ReferenceTranslation Grid. Reference Text Formatting Translation Rules, ReferenceObject Formatting Translation Rules, Reference Top NavigationTranslation Rules, Reference Bottom Navigation Translation Rules, andReference Look and Feel Translation Rules are defined. CorrespondingClient Translation Grid, Client Text Formatting Translation Rules,Client Object Formatting Translation Rules, Client Top NavigationTranslation Rules, Client Bottom Navigation Translation Rules, andClient Look and Feel Translation Rules are defined for each ClientDevice in the plurality of Client Devices of different characteristicsin terms of operating system, hardware, and look and feel.

In this preferred embodiment of the invention, a User Interface for afirst Client Device in the plurality of different characteristics interms of operating system, hardware, and look and feel is generated byscaling the objects according to the relative screen sizes andresolution of the Reference Client Device and first Client Device,placing the objects on the Client Translation Grid in the grid positioncorresponding to the object placed in the Reference Translation Grid,and applying the Client Text Formatting Translation Rules, Client ObjectFormatting Translation Rules, Client Top Navigation Translation Rules,Client Bottom Navigation Translation Rules, and Client Look and FeelTranslation Rules.

Another preferred embodiment of the invention includes computing aReference Fill Score for the User Interface for the Reference ClientDevice, a Client Fill Score for the generated User Interface for thefirst Client Device, and a Translation Ratio. The Translation Ratio iscompared with a Translation Threshold to determine that the generatedUser Interface for the first Client Device offers the end user on thefirst Client Device the same user experience that the User Interface forthe Reference Client Device offers the end user on the Reference ClientDevice.

Another preferred embodiment of the invention includes a method toadjust the generated User Interface for the first Client Device if, bycomparing the computed Translation Ratio with a Translation Threshold,it is determined that the generated User Interface for the first ClientDevice does not offer the end user on the first Client Device the sameuser experience that the User Interface for the Reference Client Deviceoffers the end user on the Reference Client Device. The adjustment ofthe generated User Interface for the first Client Device makes the userexperience offered to the end user on the first Client Device moresimilar to the user experience offered to the end user on the ReferenceClient Device.

This preferred embodiment of the invention includes a method todetermine that a generated User Interface for the first Client Device,which does not offer the end user on the first Client Device the sameuser experience that the User Interface for the Reference Client Deviceoffers the end user on the Reference Client Device, cannot be furtherautomatically adjusted in order to make the user experience offered tothe end user on the first Client Device more similar to the userexperience offered to the end user on the Reference Client Device.

Another preferred embodiment of the preferred invention includes theapparatus comprising Computing devices with dedicated servers runningthe System Solution that takes as input a User Interface designed for aReference Client Device and automatically generates a plurality of UserInterfaces designed to run on a plurality of Client Devices of differenttypes in terms of their operating system, hardware, and look and feelcharacteristics.

In another preferred embodiment of the invention, the System Solutionincludes the apparatus comprising Computing devices with dedicatedservers which determine whether a generated User Interface for a firstClient Device offers the end user the same user experience of a UserInterface for a Reference Client Device of different characteristics. Ifthe a generated User Interface for a first Client Device does not offerthe end user the same user experience as a User Interface for aReference Client Device, the apparatus identifies which portions of theUser Interface for the first Client Device do not offer the end user thesame user experience as a User Interface for a Reference Client Device.

In accordance with another preferred embodiment of the invention, aSystem Apparatus comprising a Reference Client Device with a ReferenceApplication Client with an first Operating system and a first screen ofa first aspect ratio and a first screen resolution, a plurality ofObjects displayed on a User Interface of the Reference Client Device, aClient Translator and Generator receives the User Interface of theReference Application Client and automatically generates and translatesa plurality of User Interfaces of Application Clients other than theReference Application Client for a plurality of Client Devices, eachApplication Client with one of a plurality of Operating Systems and acorresponding one of a plurality of different screens with a differentaspect ratio and a different screen resolution, and the plurality of theUser Interfaces of the Application Client display the plurality ofObjects on the plurality of different screens. The System Apparatusfurther comprising an Automatic Application Client Generator receivesdata from a Client Data Model and generates a Reference ApplicationClient including the User Interface of the Reference Client Device. TheSystem Apparatus further comprising a set of Native Mobile ApplicationClients, a set of Native Nom-Mobile Application Clients, Non-NativeNon-Mobile Application Clients, Non-Native Non-Mobile Cloud ApplicationClients, and Non-Native Mobile Application Clients in the plurality ofApplication Clients. The System Apparatus further comprising a UserInterface Translator in the Client Translator and Generator thatcombines the User Interface of the Reference Client Device with theplurality of Client Devices to generate a plurality of User Interfacesthat feature the plurality of Objects of the Reference Client Device foreach of the plurality of Client Devices. The System Apparatus furthercomprising the Reference Client Device providing a reference parametersto translate the reference parameters into the parameters used in theplurality of Client devices. The System Apparatus further comprising theUser Interface of the Reference Application Client with a plurality ofpages. The System Apparatus further comprising a page with a Body Areawith a Top Navigation Area and/or a Bottom Navigation Area displayingthe plurality of Objects, the System Apparatus further comprising aTranslation Grid that partitions the Body Area on the Reference ClientDevice and each Client Device in the plurality of Client Devices intoTranslation Grid Nodes, Translation Grid Height and, Translation Gridwidth parameters, and a set of translation rules for the ReferenceClient Device and each Client Device in the plurality of Client Devices,and the System Apparatus wherein the translation grid is used to placethe plurality of Objects on the Body Area of each Client Device in theplurality of Client Device. The System Apparatus further comprising aContent Object Picture with a Picture Format, Content Object Video witha Video Format, a Context Object Text with a Text Format, a Shape Objectwith a Shape format, and a Navigation Object with a Navigation ObjectFormat forming the plurality of Objects.

In accordance with another preferred embodiment of the invention, amethod of automatically generating an optimal translation comprising thesteps of selecting each Client Device in a plurality of Client Devices,each Client Device with one of a plurality of Operating Systems and acorresponding one of a plurality of different screens each with adifferent aspect ratio and a different screen resolution, providing aPage with a Body Area, adjusting a Translation Grid to the Body Area ofa selected Client Device, converting sizes and a resolution of each of aplurality of Objects, placing the plurality of Objects on theTranslation Grid of the selected Client Device filling up a portion ofthe Translation Grid, computing a Fill Score of the selected ClientDevice of the filled portion of the Translation Grid area, computing aTranslation Ratio as the ratio of the Fill Score of the selected ClientDevice and the Fill Score of a Reference Client Device, comparing if thecomputed Translation Ratio is less than or equal to a TranslationThreshold, and generating the optimal translation automatically of aUser Interface of the Reference Client Device into a plurality of UserInterfaces of each Client Device in the plurality of Client Devices. Themethod further comprising the steps of placing the Top Navigation Areaand/or Bottom Navigation Area at the Top and/or Bottom of the Body Areaand in addition the method further comprising the steps of checking ifthe Top and/or Bottom Navigation Rules are valid. The method furthercomprising the steps of identifying the plurality of Objects from a listcomprising Content Object Picture with a Picture Format TranslationRules, Content Object Video with a Video Format Translation Rules, aContext Object Text with a Text Format Translation Rules, a Shape Objectwith a Shape Format Translation Rules, and a Navigation Object with aNavigation Object Format Translation Rules. The method wherein aTranslation Grid that partitions the Body Area into Translation GridNodes, Translation Grid Height and, Translation Grid width parametersand the translation grid is used to place the plurality of Objects onthe Body Area of a plurality of different screens, simultaneously.

In accordance with another preferred embodiment of the invention, amethod of identifying when a translation is suboptimal comprising thesteps of selecting each Client Device in a plurality of Client Devices,each Client Device with one of a plurality of Operating Systems and acorresponding one of a plurality of different screens each with adifferent aspect ratio and a different screen resolution, providing aPage with a Body Area, adjusting a Translation Grid to the Body Area ofa selected Client Device, converting sizes and a resolution of each of aplurality of Objects, (a) placing the plurality of Objects on theTranslation Grid of the selected Client Device filling up a portion ofthe Translation Grid, (b) computing a Fill Score of the selected ClientDevice of the filled portion of the Translation Grid area, (c) computinga Translation Ratio as the ratio of the Fill Score of the selectedClient Device and the Fill Score of a Reference Client Device, (d)comparing if the computed Translation Ratio is less than or equal to aTranslation Threshold and identifying that the translation is optimal,and generating the optimal translation automatically of a User Interfaceof the Reference Client Device into a plurality of User Interfaces ofeach Client Device in the plurality of Client Devices, otherwise, (e)determining if a maximum number of iterations have been reached then thetranslation is suboptimal and identify the suboptimal translation to aSystem Solution Expert, otherwise, applying Text Formatting TranslationRules to a Context Object Text from the plurality of Objects, applyingObject Formatting Translation Rules to the remaining plurality ofObjects, computing new Object Sizes, and repeating steps (a)-(e). Themethod further comprising the steps of placing the Top Navigation Areaand/or Bottom Navigation Area at the Top and/or Bottom of the Body Area,and in addition the method further comprising the steps of checking ifthe Top and/or Bottom Navigation Rules are valid. The method furthercomprising the steps of identifying the remaining plurality of Objectsfrom a list comprising Content Object Picture with a Picture FormatTranslation Rules, Content Object Video with a Video Format TranslationRules, a Shape Object with a Shape Format Translation Rules, and aNavigation Object with a Navigation Object Format Translation Rules. Themethod wherein a Translation Grid that partitions the Body Area intoTranslation Grid Nodes, Translation Grid Height and, Translation Gridwidth parameters and the translation grid is used to place the pluralityof Objects on the Body Area of a plurality of different screens,simultaneously.

BRIEF DESCRIPTION OF THE DRAWINGS

Please note that the drawings shown in this specification may notnecessarily be drawn to scale and the relative dimensions of variouselements in the diagrams are depicted schematically. The inventionspresented here can be embodied in many different forms and should not beconstrued as limited to the embodiments set forth herein. Rather, theseembodiments are provided so that this disclosure will be thorough andcomplete, and will fully convey the scope of the invention to thoseskilled in the art. In other instances, well-known structures andfunctions have not been shown or described in detail to avoidunnecessarily obscuring the description of the embodiment of theinvention. Like numbers refer to like elements in the diagrams.

FIG. 1A depicts a Client Device coupled to a server and an ApplicationStore and provides some examples of Client Devices.

FIG. 1B depicts a Client Device coupled to a client/server.

FIG. 2A shows a Client Device with a coupling to a bank of servers, anApplication Store, and the internal hardware/software structure of theClient Device.

FIG. 2B depicts a more detailed description of a server being a subsetof Computer hardware with software, a Database and the server.

FIG. 3A presents a Native Application Client and how it relates to thelayered stacks of the hardware/software representation of a ClientDevice.

FIG. 3B illustrates a Non-Native Application Client and how it relatesto the layered stacks of the hardware/software representation of aClient Device.

FIG. 4 shows the flow of how a Native Application Client is approved anddownloaded by an Application Store to a Client Device.

FIG. 5 depicts a Two-Layer Native Application Client in accordance withthe present invention.

FIG. 6A shows a Two-Layer Application Client being downloaded to aClient Device for the first time in accordance with the presentinvention.

FIG. 6B presents a Dynamic Layer a Two-Layer Application Client beingdownloaded to a Client Device in accordance with the present invention.

FIG. 7 shows different Native Application Client Devices havingdifferent Operating Systems and different Hardware in accordance withthe present invention.

FIG. 8 illustrates shows different Non-Native Application Client Deviceshaving different Operating Systems and different Hardware in accordancewith the present invention.

FIG. 9 depicts Applications and Application Clients being generatedautomatically in accordance with the present invention.

FIG. 10 illustrates the flow to generate Application Clients from aReference Application Client in accordance with the present invention.

FIG. 11A shows the User Interface Translation Process on a first Devicein accordance with the present invention.

FIG. 11B illustrates the User Interface Translation Process on a secondDevice in accordance with the present invention.

FIG. 12 depicts the structure of the Application Client in accordancewith the present invention.

FIG. 13 illustrates the structure of a Page in accordance with thepresent invention.

FIG. 14 depicts a Page containing different Objects in accordance withthe present invention.

FIGS. 15A and 15B illustrates a Translation grid with Translation GridNodes, Height, and width in accordance with the present invention.

FIG. 16 depicts the process for preparing all Clients for Translation inaccordance with the present invention.

FIG. 17 shows the process of placing Objects on the ReferenceTranslation Grid of a Reference Client Device in accordance with thepresent invention.

FIG. 18 depicts a flow chart of an algorithm to determine optimal andsub-optimal Translation in accordance with the present invention.

DETAILED DESCRIPTION OF THE INVENTION

The System Solution offers the ownership, control and beneficial use ofthis inventive idea. The System solution offers the beneficial use tothe Business Entity by providing the Business Entity with ApplicationClients adapted to the characteristics of all the Client Devices whichthe Business Entity desires the Application Client to run on. TheApplication Clients provided by the System Solution comprise a pluralityof Native Application Clients that run on Mobile, Non-Mobile, and CloudClient Devices of different types and a plurality of Non-NativeApplication Clients that run on Mobile, Non-Mobile, and Cloud ClientDevices of different types.

The System Solution is the owner of all Application Components,including Native and Non-Native Application Client, automaticallygenerated by the System Solution. The System Solution creates and hostsApplications and generates Application Clients for different BusinessEntities (each Business Entity is a System Solution customer). TheSystem Solution provides a complete environment for the creation,hosting, updating, and management of the Application. The ApplicationServers generated by the System Solution for all Business Entities arehosted in a multi-tenant environment in the Cloud, but each BusinessEntity “feels” like it is provided a dedicated Application Server. TheSystem Solution architecture also applies with minor changes to ascenario where the System Solution Application Server run on dedicatedservers owned by the Business Entity, rather than in the Cloud. In thisscenario, the System Solution has access to control and offer beneficialuse for those servers that are coupled to the Cloud.

Business Entities deploy their Applications and Application Clients toreach Consumers (i.e., the customers of that Business Entity served bySystem Solution). The Consumers are the primary End Users of theApplication Clients generated by the System Solution. The BusinessEntities are the End Users of the Dashboards and the Application Serverthat the System Solution provides to each Business Entity for managingthe corresponding Application Clients.

Mobile Client Devices (cellular phones, smartphones, wearable devices,and tablets) and Non-Mobile Client Devices (laptops, desktops, andInternet-enabled TV sets) are coupled to the internet by wired (aphysical interconnect), wirelessly (waves through space), or bothwired/wireless networks. The wireless connectivity can be cellular (3G,4G, etc.), Wi-Fi, Bluetooth, WiMax, etc. The network interconnectingthese components is called the Communication network. The Client Device1-2 has the Application Client which is the actual application softwarerunning on device. The term “Mobile” when used alone or in a largerphrase “Mobile Client Devices” can also imply the terms Mobile,Non-Mobile or in the Cloud. The term Mobile Client at times will bereferred to as the Client Device. The term Application highlights thefact that the application built by the System Solution comprises aplurality of Application Components, and includes a portion of theApplication that runs on the Client Device (the Application Client) anda portion of the application that runs on a server (the ApplicationServer). The term “Application Client” refers to the portion of theapplication running on the Client Device. The term “Application Client”encompasses the Application Client running on a mobile Client Device, anon-mobile Client Device or even in the Cloud. The Cloud can run aportion of the Application Client in the server while the remainingportion of the Application Client can run on the Client Device,simultaneously. The term “Application Client” is used to refer to bothNative and Non-Native Application Client. The term “Mobile ApplicationClient” will be used for both Native and Non-Native Application Clientsrunning on a mobile Client Device, but it also applies to Client Devicesthat are non-mobile or in the Cloud.

In all cases, the Application Clients provide the End User with a UserInterface which provides the end user with at least one mode of inputand at least one mode of output. The User Interface provides the meansto the end users through which the end user navigates and interacts withthe Application Client.

Each Application includes a family of Application Clients. EachApplication Client is designed to run on a Client Device of a certaintype, part of a plurality of Client Devices. The Client Devices in theplurality of Client Devices have different characteristics in terms ofhardware, operating system, and “look and feel” of each device. Inparticular, each Client Device in the plurality of Client Devices mayhave a different screen in terms of resolution, aspect ratio, and size.

The family of Application Clients includes a set of Native MobileApplication Clients, one per mobile Client Device. The family ofApplication Clients also includes a set of Native Non-Mobile ApplicationClients, one per non-mobile Client Device. The family of ApplicationClients also includes Non-Native Mobile and Non-Mobile ApplicationClients, and Cloud Application Clients residing in the Cloud. Native,Non-Native, and Cloud Application Clients can be automatically generatedby the System Solution.

A Native Application Client executable depends on the operating systemof the Client Device on which the Native Application Client is runningon. Thus, the executable of a Native Application Client to run ondifferent Client Devices may be different. The set of automaticallygenerated Native Mobile Application Clients provides a Native MobileApplication Client per each mobile Client Device which the MobileApplication is desired to run on. The executable of a Native MobileApplication Client designed to run on a first mobile Client Device isgenerated to run on the operating system of the first mobile ClientDevice and may be different from the executable of a Native MobileApplication Client designed to run on a second mobile Client Device. Theexecutable of a Native Non-Mobile Application Client designed to run ona first non-mobile Client Device is generated to run on the operatingsystem of the first non-mobile Client Device and may be different fromthe executable of a Native Non-Mobile Application Client designed to runon a second non-mobile Client Device.

The User Interface of a Native Application Client to run on differentClient Devices may be different. The User Interface of a NativeApplication Client depends on the operating system, the hardware, andthe “look and feel” of each Client Device. In particular, the UserInterface depends on the characteristics of the screen of each ClientDevice in terms of screen resolution, aspect ratio, and size. The UserInterface of a Native Mobile Application Client designed to run on afirst mobile Client Device is adapted to the characteristics in terms ofoperating system, hardware and “look and feel of the first mobile ClientDevice and may be different from the User Interface of a Native MobileApplication Client designed to run on a second mobile Client Device,which is adapted to the characteristics in terms of operating system,hardware and “look and feel of the second mobile Client Device. The UserInterface of a Native Non-Mobile Application Client designed to run on afirst non-mobile Client Device is adapted to the characteristics interms of operating system, hardware and “look and feel of the firstnon-mobile Client Device and may be different from the User Interface ofa Native Non-Mobile Application Client designed to run on a secondnon-mobile Client Device, which is adapted to the characteristics interms of operating system, hardware and “look and feel of the secondnon-mobile Client Device. The User Interface of a Native ApplicationClient must be adapted to the characteristics in terms of operatingsystem, hardware, and look and feel of each Client Device on which theNative Application Client is desired to run.

A Non-Native Application Client does not depend on the operating systemof the Client Device on which the Non-Native Application Client isrunning on, since it runs on the Web Browser that is running on eachClient Device. However, the User Interface of a Non-Native ApplicationClient to run on different Client Devices may be different. The UserInterface of a Non-Native Application Client depends on the hardware andthe “look and feel” of each Client Device. In particular, the UserInterface depends on the characteristics of the screen of each ClientDevice in terms of screen resolution, aspect ratio, and size. The UserInterface of a Non-Native Application Client must be adapted to thecharacteristics in terms of hardware and look and feel of each ClientDevice on which the Non-Native Application Client is desired to run. TheNon-Native Application Client is written in a programming language thatis understood by the web browser running on the Client Device.Typically, such a programming language, for example HTML5, providescertain functionality that allows the web browser running on the ClientDevice to adapt the User Interface of the Non-Native Application Clientto the characteristics of the Client Device. However, because ofpossible limitations in the adaptation capabilities that the web browserrunning on the Client Device provides, the “adapted” User Interface maynot offer the same user experience in all Client Devices.

The automatic generation of the set of Native Mobile ApplicationClients, the set of Native Non-Mobile Application Clients, Non-NativeApplication Clients, and Cloud Application Clients requires a ClientTranslator and Generator that translates a User Interface of anApplication Client designed to run on a Reference Client Device into aUser Interface of an Application Client designed to run on each ClientDevice in the plurality of Client Devices of different types which theApplication Client is desired to run on. The Reference Client Device maybe one of the Client Devices that the Application Client is desired torun on. The User Interface which is translated to run on a Client Devicemust adapt to the characteristics of the Client Device in terms ofoperating system, hardware, in particular screen resolution, size, andaspect ratio, and “look and feel.

The process of translating the User Interface from a User Interfacedesigned for a Reference Client Device to a User Interface adapted tothe characteristics in terms of operating system, hardware, and look andfeel for each Client Device that an Application Client is desired to runon is very complex because of the broad differences in thecharacteristics of each Client Device. Also, the User Interface is avery important part of the user experience that the Application Clientprovides to the end user, since it provides the “sensorial” experience(especially visual) of the interaction with the Application Client.Since end users have scarce tolerance for imperfections in the UserInterface visual aspects and behavior, the translated User Interface foreach Client Device must be of very “high quality” in order to offer thesame user experience in all Client Devices.

The user experience offered by an Application Client on a Client Deviceis the result of many factors, many of the factors qualitative innature, since the user experience is a qualitative experience. Forexample, pictures and videos displayed by a User Interface should notlook distorted. Text should use proper fonts and font sizes, bewell-spaced and not truncated. Buttons and other navigation elementsshould be properly spaced, and follow the look and feel of the ClientDevice. Embellishment effects such as shapes, outlines, and shadowsshould be properly displayed. The “composition” of the User Interface,i.e., the relationship among the different graphical elements displayedby the User Interface should be visually pleasant in all Client Devices.For example, the different elements displayed by the User Interfaceshould not look too large or too small, areas of the screen should notlook unnaturally empty, the distance between any two elements should besimilar in relative terms on all Client Devices, elements that do notoverlap in the Reference Client Device User Interface should not overlapin any User Interface, etc.

Because of the wide variation in the characteristics of different ClientDevices in terms of operating system, hardware, and “look and feel,” afirst User Interface that “looks good” on a first Client Device may“look poor” when the first User Interface is translated to a secondClient Device. For example, a set of buttons that appear properly spacedwhen displayed on the first Client Device, may appear too closely-spacedwhen displayed on the second Client Device, and the end user may findthem awkward to use them on the second Client Device. Another example isa picture that may appear properly sized when displayed on a firstClient Device, but may appear distorted when displayed on a secondClient Device featuring a screen of a different aspect ratio than thefirst Client Device. Especially in mobile Client Devices, which usescreens of relatively small sizes and typically run Application Clientswith User Interfaces that are very carefully designed and highlyfine-tuned, even small changes in the elements or composition of theUser Interfaces may be very noticeable and affect the user experienceoffered by the Application Client to the end user.

The problem of properly adapting a User Interface to the characteristicsof Client Devices of different types is especially relevant for NativeApplication Clients. The problem also applies to a certain extent toNon-Native Application Clients. In the case of Non-Native ApplicationClients, the web browser running on the Client Device provides certaincapabilities to adapt a Non-Native Application Client to thecharacteristics of the Client Device. However, the adaptationcapabilities provided by the web browser running on a certain ClientDevice may be limited and the adaptation may not result in the same userexperience in all Client Devices.

Since a User Interface “looks good” or does not “look good” on a ClientDevice based on a number of factors that are qualitative in nature, the“measurement” of the result of the User Interface translation todifferent Client Devices is difficult, since a “good” or “bad”translation also depends on factors that are qualitative in nature.However, certain metrics provide a quantitative estimate of the qualityof the User Interface translation.

FIG. 5 depicts a Two-Layer Native Application Client 5-1 which is aNative Application Client that consists of two layers: a Dynamic Layer5-3 and a Native Layer 5-2. The Native Layer 5-2 runs directly on theoperating system 2-13 of the Client Device 1-2 by using the systemlibraries 3-3 that are part of the operating system 2-13. The DynamicLayer 5-3 does not run directly on the operating system 3-3, but insteadruns on the Native Layer 5-2 by making use of software libraries andfunctional blocks provided in the Native Layer 5-2. The Native Layer 5-2is an executable that depends on the Client Device 1-2 and needs to bedownloaded and installed on the Client Device 1-2 using an installationmanager external to the Two-Layer Native Application Client 5-1. TheNative Layer 5-2 needs to be downloaded from the application store. TheDynamic Layer 5-3 does not need to be downloaded from the applicationstore, but can be downloaded directly from an Application Server that ispart of the System Solution. We use the term “Dynamic Native ApplicationClient” as synonymous of the term “Two-Layer Native Application Client”.The operating system runs on the hardware 2-16.

FIG. 6A illustrates the process of downloading the Two-Layer NativeApplication Client 5-1 to a Client Device 1-2 for the first time. Thisprocess is similar to the process of downloading a Native ApplicationClient 3-1 to the Client Device depicted in FIG. 4. A Business Entity4-1 creates a new application which comprises a Two-Layer NativeApplication Client 5-1. The new Two-Layer Native Application Client 5-1is submitted 4-3 to the Application Store 1-10 for an approval process4-4. Once the new Two-Layer Native Application Client is accepted 4-5,information is passed to the Application Store 1-10 to make the newTwo-Layer Native Application Client available for download into a ClientDevice 1-2. A Client Device 1-2 which desires the Two-Layer NativeApplication Client 5-1 downloads the Two-Layer Native Application Clientfrom the corresponding application store 1-10. Once the Two-Layer NativeApplication Client is downloaded to the Client Device, it is installed4-6 on the Client Device so it can run on the operating system 2-13 ofthe Client Device. The Two-Layer Native Mobile Application Client 5-1executable depends on the operating system (OS) as an iPhone wouldrequire a different executable than an Android™ phone. If the BusinessEntity modifies the Native Layer 5-2, it needs to submit the new versionof the Native Layer 5-2 to the application store for re-approval inorder to make it available for download to the Client Device. In orderto install the updated version of the Native Layer on the Client Device,the existing version of the Native Layer, if running on the ClientDevice 1-2, must be stopped and deleted from the memory of the ClientDevice 1-2 in order for the new version of the Native Layer to beinstalled on the Client Device. The Native Layer cannot be updated “onthe fly” while the Native Application Client 5-1 is running on theClient Device 1-2. The Dynamic Layer 5-1 runs on the Native Layer 5-2.

FIG. 6B illustrates the process of downloading an updated Dynamic Layer6-4 to the Client Device. If the Business Entity 4-1 modifies theDynamic Layer 5-1 and creates an Updated Dynamic Layer 6-2, it can makeit available for download 6-4 directly from an Application Server 6-3that is part of the System Solution or is owned by the Business Entity.The new version 6-2 of the Dynamic Layer 5-3 is made available fordownload to the Client Device without having the Business Entity submitit for approval to the application store 1-10. The updated Dynamic Layer6-2 can be downloaded and installed 6-4 in the Client Device 1-2 whilethe Two-Layer Native Application Client 5-1 is running on the ClientDevice. The update of the existing Dynamic Layer can be achieved usingan update manager 6-6 that is internal in the Native Layer 5-2 of theTwo-Layer Native Application Client 3-1. Once the Updated Dynamic Layer5-3 is installed on the Client Device 1-2, the new application clientfunctionality and new user experience is provided to the end user. TheNative Layer 5-2 runs on the operating system 2-13 which in turn runs onthe hardware 2-16.

FIG. 7 illustrates a plurality of Client Devices comprising ClientDevice 1 1-2 to Client Device N 1-2 b. Each Client Device is of adifferent Client Device type and different characteristic, such ashardware, operating system, and “look and feel” of each device. Forexample, a first Client Device can be an iPhone 4™, a second ClientDevice can be an iPhone 5™, a third Client Device can be an iPad™, afourth Client Device can be an iPad Mini™, a fifth Client Device can bea Samsung Galaxy II™ smartphone running the Android™ operating system, asixth Client Device can be a Nokia Lumia™ smartphone running the WindowsMobile™ operating system, a seventh Client Device can be a SamsungNotes™ tablet with 10″ screen running the Android™ operating system, aneighth Client Device can be a Samsung Notes™ tablet with 7″ screenrunning the Android™ operating system, a ninth Client Device can be aDell™ laptop, and so on. Client Device 1 1-2 comprises an OperatingSystem 1 2-13 and a Hardware 1 2-16 which comprises a Screen 1 2-10 witha certain Screen Resolution, Aspect Ratio and Size. Client Device 1 hasa certain “Look and Feel” Client Device 1 7-1. Client Device 2 1-2 acomprises an Operating System 2 2-13 a and a Hardware 2 2-16 a whichcomprises a Screen 2 2-10 a with a certain Screen Resolution, AspectRatio and Size. Client Device 2 has a certain “Look and Feel” ClientDevice 2 7-1 a. Client Device N 1-2 b comprises an Operating System N2-13 b and a Hardware N 2-16 b which comprises a Screen N 2-10 b with acertain Screen Resolution, Aspect Ratio and Size. Client Device N has acertain “Look and Feel” Client Device N 7-1 b. Operating System 1 2-13may differ from Operating System 2 2-13 a, which in turn may differ fromOperating System N 2-13 b. Hardware 1 2-16 may differ from Hardware 22-16 a, which in turn may differ from Hardware N 2-16 b. Specifically,Screen 1 2-10 may differ from Screen 2 2-10 a, which in turn may differfrom Screen N 2-10 b in terms of screen resolution, or aspect ratio andsize. “Look and feel” Client Device 1 7-1 may differ from “Look andfeel” Client Device 2 7-1 a, which in turn may differ from “Look andfeel” Client Device N 7-1 b.

The “Look and Feel” of a Client Device is due to the fact that themanufacturer of a certain operating system or Client Device encouragescertain practices that developers of Application Client User Interfacesrunning on their devices should follow, so all Application Clientsrunning on the Client Device have some general common behavior and anend user is comfortable even the first time he/she uses a User Interfaceof a new Application Client, since the end user can “navigate” the newApplication Client, at least to some extent, by applying “knowledge”gained by navigating other Application Clients. The “Look and Feel”often depends on the operating system and on the device itself. Forexample, the “look and feel” of an iPhone™ is different from the “lookand feel” of a device running the Android™ operating system or from adevice running the Blackberry™ operating system. The “look and feel” ofan iPhone™ is also slightly different from the “look and feel” of aniPad™, even if the two devices run the same operating system. Forexample, in an Application Client running on an iPhone, the Tab Bar istypically at the bottom of the screen, in an Application Client runningon Android phone can be at the top. Another example is that in anApplication Client running on iPhone there is a “Home” button in theUser Interface to go back to a main landing page in the ApplicationClient. In an Application Client running on many Android Client Devices,typically there is no “Home” button because there is a physical “Home”button in the Client Device. In another example, in an ApplicationClient running on iPhone, when displaying a choice menu asking the enduser for a “Yes” or “No” answer, the “Yes” is on the left, in Android,the “Yes” is on the right.

A Native Application Client executable depends on the operating systemof the Client Device on which the Native Application Client is runningon. Thus, the executable of a Native Application Client to run ondifferent Client Devices may be different. For example, the executableof the Native Application Client 3-1 to run on Client Device 1 1-2 maybe different from the executable of the same Native Application Client3-1 a to run on Client Device 2 1-2 a, which in turn may be differentfrom the executable of the same Native Application Client 3-1 b to runon Client Device N 1-2 b.

The User Interface of a Native Application Client when run on differentClient Devices may be different. The User Interface of a NativeApplication Client depends on the operating system, the hardware, andthe “look and feel” of each Client Device. In particular, the UserInterface depends on the characteristics of the screen of each ClientDevice in terms of screen resolution, aspect ratio, and size. Forexample, the User Interface 3-5 of the Native Application Client 3-1 torun on Client Device 1 1-2 may be different from the User Interface 3-5a of the same Native Application Client 3-1 a to run on Client Device 21-2 a, which in turn may be different from the User Interface 3-5 b ofthe same Native Application Client 3-1 b to run on Client Device N 1-2b. The User Interface of a Native Application Client must be adapted tothe characteristics in terms of operating system, hardware, and look andfeel of each Client Device on which the Native Application Client isdesired to run. Each Native Application Client includes a ClientFunctionality 3-2, 3-2 a and 3-2 b, respectively.

FIG. 8 is similar to FIG. 7, but addresses the case of Non-NativeApplication Clients. FIG. 8 illustrates the same plurality of ClientDevices comprising Client Device 1 1-2 to Client Device N 1-2 b shown inFIG. 7, each Client Device of a different Client Device type anddifferent characteristic, such as hardware, operating system, and “lookand feel” of each device.

A Non-Native Application Client does not depend on the operating systemof the Client Device on which the Non-Native Application Client isrunning on, since it runs on the Web Browser 1 8-2, Web Browser 2 8-2 a,and Web Browser 3 8-2 b that is running on each Client Device. The WebBrowser running on each Client Device supports the “look and feel” ofeach device. The User Interface of a Non-Native Application Client torun on different Client Devices may be different. The User Interface ofa Non-Native Application Client 8-3 to 8-3 b depends on the hardware2-16 to 2-16 b, respectively, and the “look and feel” 8-1 to 8-1 b,respectively of each Client Device. In particular, the User Interfacedepends on the characteristics of the screen of each Client Device interms of screen resolution, aspect ratio, and size. For example, theUser Interface 8-5 of the Non-Native Application Client 8-3 to run onClient Device 1 1-2 may be different from the User Interface 8-5 a ofthe same Non-Native Application Client 8-3 a to run on Client Device 21-2 a, which in turn may be different from the User Interface 8-5 b ofthe same Non-Native Application Client 8-3 b to run on Client Device N1-2 b. The User Interface of a Non-Native Application Client must beadapted to the characteristics in terms of hardware and look and feel ofeach Client Device on which the Non-Native Application Client is desiredto run. The Non-Native Application Client is written in a programminglanguage that is understood by the web browser running on the ClientDevice. Typically, such a programming language, for example HTML5,provides certain functionality that allows the web browser running onthe Client Device to adapt the User Interface of the Non-NativeApplication Client to the characteristics of the Client Device. However,because of possible limitations in the adaptation capabilities that theweb browser running on the Client Device provides, the “adapted” UserInterface may not offer the same user experience in all Client Device 11-2 comprises an Operating System 1 1 2-13 and a Hardware 1 1 2-16 whichcomprises a Screen 1 2-10 with a certain Screen Resolution, Aspect Ratioand Size. Client Device 1 has a certain “Look and Feel” for Web browser1 Client Device 1 8-1. Client Device 2 1-2 a comprises an OperatingSystem 2 2-13 a and a Hardware 2 2-16 a which comprises a Screen 2 2-10a with a certain Screen Resolution, Aspect Ratio and Size. Client Device2 has a certain “Look and Feel” for Web browser 2 Client Device 2 8-1 a.Client Device N 1-2 b comprises an Operating System N 2-13 b and aHardware N 2-16 b which comprises a Screen N 2-10 b with a certainScreen Resolution, Aspect Ratio and Size. Client Device N has a certain“Look and Feel” for Web browser N Client Device N 8-1 b. Each Non-NativeApplication Client includes a Client Functionality 3-2, 3-2 a and 3-2 b,respectively. Each Non-Native Application Client includes a ClientFunctionality 3-2, 3-2 a and 3-2 b, respectively.

FIG. 9 depicts a method and apparatus to automatically generate anApplication consisting of several Application Components. A BusinessEntity 4-1 defines a Service Representation 9-1 and Business Entity Data9-2. An Automatic Data Model Generator 9-3 takes the ServiceRepresentation 9-1 and the Business Entity Data 9-2 as inputs andautomatically generates a Data Model 9-4, and from the Data Model 9-4 itgenerates a Common Data Model 9-5, a Server Data Model 9-6 and a ClientData Model 9-7. Using the generated Common Data Model 9-5, Server DataModel 9-6, and Client Data Model 9-7, an Automatic Application Generator9-8 automatically generates all the Application Components. Thegenerated Application Components include an Application Server 9-9, aset of Native Mobile Application Clients 9-10, a set of NativeNon-Mobile Application Clients 9-11, a set of Non-Native ApplicationClients 9-12, Client Server Protocols 9-13, Dashboards 9-14, and OtherApplication Components 9-15.

The method and apparatus depicted in FIG. 9 is explained in detail inU.S. patent application Ser. No. 13/833,589 titled “Apparatus for SingleWorkflow for Multi-Platform Mobile Application Creation and Delivery”filed on Mar. 15, 2013, in U.S. patent application Ser. No. 13/833,669titled “Method for Single Workflow for Multi-Platform Mobile ApplicationCreation and Delivery” filed on Mar. 15, 2013, and in U.S. patentapplication Ser. No. 13/833,849 titled “Dynamic User Interface DeliverySystem” filed on Mar. 15, 2013, which are incorporated in reference intheir entirety. What is relevant in this application is that the set ofgenerated Native Mobile Application Clients 9-10 comprises a NativeMobile Application Client executable for each mobile Client Device thatthe Native Mobile Application Client is desired to run on. The UserInterface of each Native Mobile Application Client in the set ofgenerated Mobile Application Clients 9-10 is adapted to thecharacteristics in terms of operating system, hardware, and look andfeel of the corresponding mobile Client Device that the Native MobileApplication Client is desired to run on. The set of generated NativeNon-Mobile Application Clients 9-11 comprises a Native Non-MobileApplication Client executable for each non-mobile Client Device that thegenerated Native Mobile Application Client is desired to run on. TheUser Interface of each Native Non-Mobile Application Client in the setof Non-Mobile Application Clients 9-11 is adapted to the characteristicsin terms of operating system, hardware, and look and feel of thecorresponding non-mobile Client Device that the Native MobileApplication Client is desired to run on. The User Interface of theNon-Native Application Clients 9-12 is adapted to the characteristics interms of hardware and look and feel of the corresponding Client Devicethat the Native Mobile Application Client is desired to run on.

FIG. 10 provides further detail of the Automatic Client Generationprocess, which is part of the method and apparatus depicted in FIG. 9.From the Client Data Model 9-7, the Automatic Application ClientGenerator 10-1, which is part of the Automatic Application Generator9-8, first automatically generates a Reference Application Client 10-2.The Reference Application Client 10-2 is an Application Client whoseexecutable is compiled to run on a Reference Client Device and whoseUser Interface is adapted to the characteristics in terms of operatingsystem, hardware, and look and feel of the Reference Client Device. TheReference Client Device may be one of the Client Devices that theApplication Client is desired to run on. For example, the iPhone 5™ maybe picked as the Reference Client Device, and the Reference ApplicationClient 10-2 is generated and adapted to run on the iPhone 5™. Once theReference Application Client 10-2 is generated, the Client Translatorand Generator 10-3 translates the executable and User Interface andgenerates the set of Native Mobile Application Clients 9-10, the set ofNative Non-Mobile Application Client 9-11, the Non-Native MobileApplication Clients 10-5, and the Non-Native Non-Mobile and CloudApplication Clients 10-4 for all the Client Device on which theApplication Client is desired to run on.

The process of translating the User Interface from a User Interfacedesigned for the Reference Client Device to a User Interface adapted tothe characteristics in terms of operating system, hardware, and look andfeel for each Client Device that an Application Client is desired to runon is very complex because of the broad differences in thecharacteristics of each Client Device. This problem is especiallyrelevant for Native Application Clients. The problem also applies to acertain extent to Non-Native Application Clients. In the case ofNon-Native Application Clients, the web browser running on the ClientDevice provides certain capabilities to adapt a Non-Native ApplicationClient to the characteristics of the Client Device. However, theadaptation capabilities provided by the web browser running on a certainClient Device may be limited and the adaptation may not result in thesame user experience in all Client Devices.

FIG. 10 also shows that the Automatic Client Generation process, whichis part of the method and apparatus depicted in FIG. 9, firstautomatically generates a Reference Application Client 10-2. TheReference Application Client 10-2 is an Application Client whoseexecutable is compiled to run on a Reference Client Device and whoseUser Interface is adapted to the characteristics in terms of operatingsystem, hardware, and look and feel of the Reference Client Device. TheReference Client Device may be one of the Client Devices that theApplication Client is desired to run on. Once the Reference ApplicationClient 10-2 is generated, the Client Translator and Generator 10-3translates the executable and User Interface and generates the set ofNative Mobile Application Clients 9-10, the set of Native Non-MobileApplication Client 9-11, the Non-Native Mobile Application Clients 10-5,and the Non-Native Non-Mobile and Cloud Application Clients 10-4 for allthe Client Device on which the Application Client is desired to run on.

FIG. 11A and FIG. 11B provide details of the User Interface Translator11-2, which is part of the Client Translator and Generator 10-3. In FIG.11A, the User Interface Translator 11-2, translates a Reference ClientDevice User Interface 11-1 into a User Interface for Client Device 111-8. The Reference Client Device User Interface 11-1 is the UserInterface designed to run on the Reference Client Device. The UserInterface for Client Device 1 11-8 is a User Interface adapted to thecharacteristics of a first Client Device 1 in the plurality of ClientDevices of different types which the Application Client is desired torun on. In the translation process, the User Interface Translator 11-2uses the characteristics of Reference Client Device Screen 11-10 interms of resolution, aspect ratio, and size, the “Look and Feel”Reference Client Device 1 11-3, the characteristics of Client Device 1Screen 1 11-4 in terms of resolution, aspect ratio, and size, and the“Look and Feel” Client Device 1 11-5 in order to perform thetranslation. FIG. 11B depicts the same process to translate theReference Client Device User Interface 11-1 and generate a UserInterface for Client Device 2 11-9, the User Interface for Client Device2 11-9 being a user interface adapted to the characteristics of a secondClient Device 2 in the plurality of Client Devices of different typeswhich the Application Client is desired to run on, the Client Device 2having different characteristics than Client Device 1. In this case, theUser Interface Translator uses the characteristics of Client Device 2Screen 2 11-6 and the “Look and Feel” Client Device 2 11-7 to performthe translation. The User Interface Translator 11-2 uses a similarprocess to translate the Reference Client Device User Interface 11-1 andgenerate a User Interface adapted to the characteristics of each ClientDevice in the plurality of Client Devices which the Application Clientis desired to run on. In the translation process, the User InterfaceTranslator 11-2 uses the characteristics of Reference Client DeviceScreen 11-10 in terms of resolution, aspect ratio, and size, the “Lookand Feel” Reference Client Device 1 11-3, the characteristics of ClientDevice 1 Screen 1 11-6 in terms of resolution, aspect ratio, and size,and the “Look and Feel” Client Device 1 11-7 in order to perform thetranslation.

FIG. 12 shows the structure of an Application Client 12-1, including aNative and a Non-Native Application Client. The Application Client 12-1comprises a plurality of Pages comprising Page 1 12-2 to Page N 12-4.Each Page in the plurality of Pages 12-2 to 12-4 includes a Page UserInterface 12-6 to 12-8. The Application Client User Interface 12-5consists of the Page User Interface of all Pages comprised in theApplication Client.

FIG. 13 shows the structure of a Page User Interface 13-1 in theplurality of Page User Interfaces comprised in the Application Client12-1. The Page User Interface has a size defined by the Page Height 13-2and Page Width 13-3. It is understood that the Page Height 13-2 and PageWidth 13-3 may differ from the Screen Height 13-10 and Screen Width13-11 which define the size of the actual physical Client Device Screen13-9 because the “Usable Area” of the Client Device Screen 13-9, whichcorresponds to the Page User Interface Size, may be smaller than thephysical screen area. For example, in a smartphone, an area at the verytop of the physical Client Device Screen is typically not usable by theApplication Client User Interface, since it displays the battery andconnectivity indicators of the Client Device. If the Usable Area of theClient Device is smaller than the physical screen area, a simpleadjustment of the Screen Height and Screen Width must be made in orderto derive the Page Height and Page Width. However, since this simpleadjustment is well understood by those skilled in the art, we use theterms “Screen Height,” “Screen Width,” and screen size to refer to theheight, width, and size of the Usable Area as well as the actualphysical area of the screen.

The Page User Interface 13-1 comprises a Top Navigation Area 13-7 ofheight Top Navigation Height 13-4, a Bottom Navigation Area 13-8 ofheight Bottom Navigation Height 13-5 and a Body Area 13-10 of sizedetermined by Body Width 13-9 and Body Height 13-6. The Top NavigationArea 13-7 may not be present, in which case the Body Area starts at thetop of the Page User Interface. The Bottom Navigation Area 13-8 may notbe present, in which case the Body Area ends at the bottom of the PageUser Interface.

FIG. 14 shows the elements that may be displayed in a Body Area 13-10 ofa Page User Interface 13-1. The Page User Interface 13-1 displays aplurality of Objects. Objects can be of different types. A plurality ofObjects of each type can be displayed in the Body Area 13-10. Objectsinclude an Object Position and an Object Format. The types of Objectsinclude the following. A Content Object Picture 14-1, which contains aPicture, and includes a size defined by a Content Object Width 14-12 anda Content Object Height 14-11, an Object Position 14-17 defined by aX-Coordinate 14-18 and Y-Coordinate 14-19 of the top left corner of theobject, and a Picture Format 14-6. A Content Object Video 14-2, whichcontains a Video, and includes a size defined by a Content Object Width14-12 and a Content Object Height 14-11, an Object Position 14-17defined by a X-Coordinate 14-18 and Y-Coordinate 14-19 of the top leftcorner of the object, and a Video Format 14-7. A Content Object Text14-3, which contains a text box, which contains text, and includes asize defined by a Content Object Width 14-12 and a Content Object Height14-11, an Object Position 14-17 defined by a X-Coordinate 14-18 andY-Coordinate 14-19 of the top left corner of the object, and a TextFormat 14-8. A Shape Object 14-4 which contains a Shape, and includes asize defined by a Shape Object Width 14-14 and a Shape Object Height14-13, an Object Position 14-17 defined by a X-Coordinate 14-18 andY-Coordinate 14-19 of the top left corner of the object, and a ShapeFormat 14-9. A Navigation Object 14-5 which contains a Button, or a Tab,or another Navigation Element and includes a size defined by aNavigation Object Width 14-16 and a Navigation Object Height 14-15, anObject Position 14-17 defined by a X-Coordinate 14-18 and Y-Coordinate14-19 of the top left corner of the object, and a Navigation ObjectFormat 14-10. For example, the Text Format 14-8 may include a Font, aFont Size, a Font Color, an Alignment, a Font Style, a Truncation, aSpacing between Words, and a Spacing between Letters. The Top NavigationArea 13-7 and the Botton Navigation Area 13-8 are also illustrated.

FIG. 15A shows the Translation Grid 15-11 applied to the Body Area 13-10of a Page User Interface 13-1. The Translation Grid 15-11 is used by theUser Interface Translator 11-2 to perform the translation of theReference Client Device User Interface 11-1 and generate the UserInterface for all Client Devices which the Application Client is desiredto run on. The Translation Grid 15-11 is defined by a Translation GridPitch that is defined by a Translation Grid Pitch Width 15-10 and aTranslation Grid Pitch Height 15-9. The Translation Grid 15-11 consistsof a plurality of Translation Grid Node i, j 15-6, numbered sequentiallyaccording to their position on the X axis and Y axis of the Body Area13-10. The Translation Grid Node 1,1 15-2 defines the top left corner ofthe Translation Grid 15-11 and coincides with the top left corner of theBody Area 13-10, the Translation Grid Node 0,m 15-5 defines the topright corner of the Translation Grid 15-11 and coincides with the topright corner of the Body Area 13-10, the Translation Grid Node n,0 15-3defines the bottom left corner of the Translation Grid 15-11 andcoincides with the bottom left corner of the Body Area 13-10,Translation Grid Node n,m 15-4 defines the bottom right corner of theTranslation Grid 15-11 and coincides with the bottom right corner of theBody Area 13-10. There are n rows of Translation Grid Nodes along theheight of the Body Area 13-10. Adjacent rows of Translation Grid Nodesare equally spaces with distance Translation Grid Pitch Height. Thereare m columns of Translation Grid Nodes along the width of the BodyArea. Adjacent columns of Translation Grid Nodes are equally spaced withdistance Translation Grid Pitch Width. The Top Navigation Area 13-7 witha Top Navigation Height 13-4 and the Bottom Navigation Area 13-8 with aBottom Navigation Height 13-5 are also illustrated.

FIG. 15B shows the Reference Translation Grid 15-12, which is theTranslation Grid applied to a Reference Client Page User Interface 15-1,which is comprised in the Reference Client Device User Interface 11-1.The Reference Translation Grid 15-12 is used by the User InterfaceTranslator 11-2. The Reference Translation Grid 15-12 is defined by theTranslation Grid Pitch Reference Client, which consists of theTranslation Grid Pitch Height Reference Client 15-13 and the TranslationGrid Pitch Width Reference Client 15-14. The Translation Grid PitchHeight Reference Client 15-13 and the Translation Grid Pitch ReferenceClient 15-14 are defined based on the resolution and screen size of theReference Client Device. The finer the Translation Grid Pitch ReferenceClient, the larger the number of Translation Grid Nodes in the ReferenceTranslation Grid and the more accurate the translation process performedby the User Interface Translator 11-2, but the higher the computationcomplexity of the User Interface Translator 11-2. The remainingidentifier numerics correspond to those described in FIG. 15A.

FIG. 16 illustrates all the translation data that needs to be preparedin order for the User Interface Translator 11-2 to perform thetranslation of the Reference Client Device User Interface 11-1 andgenerate the User Interface for all Client Devices which the ApplicationClient is desired to run on. The translation data illustrated in FIG. 16needs to be prepared for the Reference Client Device and for each ClientDevice in the plurality of Client Devices of different types that theApplication Client is desire to run on. The translation data illustratedin FIG. 16 depends only on the characteristics of each Client Device interms of operating system, hardware, and look and feel. Thus, once thetranslation data is computed for a Client Device, it is used by the UserInterface Translator 11-2 to translate any Reference User Interface tothat Client Device.

The Reference Client Device Translation Data 16-1 includes thefollowing. A Reference Translation Grid 15-12. A Reference Screen Size16-3, which consists of the Screen Height, Screen Width, and aspectratio of the screen of the Reference Client Device. If the Usable Areaof screen of the Reference Client Device is smaller than the actual areaof the physical screen of the Reference Client Device, an adjustment ismade to reflect the area of the Usable Area. A Reference ScreenResolution 16-4, which is the resolution of the screen of the ReferenceClient Device. A Reference Text Formatting Rules 16-5 which includes alist of supported fonts and font sizes, a list of the dimensions of theareas occupied by letters of different fonts and font sizes, a list ofspacing rules between letters and between words for different fonts andfont sizes, a list of rules for font styles, and other formatting rules.A Reference Object Formatting Translation Rules 16-6, which includes alist of cropping rules, border rules, and spacing rules for pictures,videos, and shapes, a list of object effect rules that includesrecommended ways to display shadows, transparencies, 3-D effects, etc.,a list of outline rules that includes recommended widths and effects ofoutlines, and other formatting rules. A Reference Top NavigationTranslation Rules 16-7 which defines the dimensions of the topnavigation area, and any other rule that applies to the top navigationarea, if present. A Reference Bottom Navigation Translation Rules 16-8which defines the dimensions of the bottom navigation area, and anyother rule that applies to the top navigation area, if present. AReference Look and Feel Translation Rules 16-9 which defines the Lookand Feel guidelines of the Reference Client Device.

The Client Device 1 Translation Data 16-1 a contains the translationdata for a first Client Device 1 with certain operating system,hardware, and look and feel characteristics that are different from thecorresponding characteristics of the Reference Client Device. The ClientDevice 1 Translation Data 16-1 a includes the following. A Client 1Translation Grid 16-10 which is the Translation Grid applied to ClientDevice 1. This grid has the same number of rows of Translation GridNodes as the Reference Translation Grid and the same number ofTranslation Grid Nodes as the Reference Translation Grid. The ratio ofthe Translation Grid Pitch Height of the Client 1 Translation Grid 16-10and the Reference Translation Grid 15-12 depends on the relative height,width, resolution, and pixel dimension of the screen of the ReferenceClient Device and of Client Device 1. A Client 1 Screen Size 1 16-11,which consists of the Screen Height, Screen Width, and aspect ratio ofthe screen of Client Device 1. If the Usable Area of screen of ClientDevice 1 is smaller than the actual area of the physical screen of theClient Device 1, an adjustment is made to reflect the area of the UsableArea. A Client 1 Screen Resolution 16-12, which is the resolution of thescreen of the Client Device 1. A Client 1 Text Formatting TranslationRules 16-13 which includes a list of fonts and font sizes supported inClient Device 1, a list of the dimensions of the areas occupied byletters of different fonts and font sizes in Client Device 1, a list ofspacing rules between letters and between words for different fonts andfont sizes in Client Device 1, a list of rules for font styles in ClientDevice 1, and other formatting rules in Client Device 1. The Client 1Text Formatting Translation Rules 16-13 also includes a list of fontsubstitution rules for fonts that are supported in the Reference ClientDevice but are not supported in Client Device 1. A Client 1 ObjectFormatting Translation Rules 16-14 which includes a list of croppingrules, border rules, and spacing rules for pictures, videos, and shapesin Client Device 1, a list of object effect rules that includesrecommended ways to display shadows, transparencies, 3-D effects, etc.,in Client Device 1, a list of outline rules that includes recommendedwidths and effects of outlines, and other formatting rules in ClientDevice 1. A Client 1 Top Navigation Translation Rules 16-15 whichdefines the dimensions of the top navigation area in Client Device 1,and any other rule that applies to the top navigation area, if present.A Client 1 Bottom Navigation Translation Rules 16-16 which defines thedimensions of the bottom navigation area in Client Device 1, and anyother rule that applies to the top navigation area, if present. A Client1 Look and Feel Translation Rules 16-17 which defines the Look and Feelguidelines of Client Device 1. The Client 1 Look and Feel TranslationRules 16-17 must include a Look and Feel Translation Rule for ClientDevice 1 for each Look and Feel Translation Rule included in theReference Look and Feel Translation Rules 16-9. Client DeviceTranslation Data is prepared in a similar fashion for all the ClientDevices in the plurality of Client Devices which the Application Clientis desired to run on.

FIG. 17 illustrates at a high level the method used by the UserInterface Translator 11-2 to perform the translation of each ReferenceClient Page User Interface 15-11 comprised in the Reference ClientDevice User Interface 11-1 and generate the User Interface for allClient Devices which the Application Client is desired to run on. EachReference Client Page User Interface 15-11 comprised in the ReferenceClient Device User Interface 11-1 is individually translated. EachObject in the plurality of Objects is associated with the TranslationGrid Node closest to the top left corner of the Object in the ReferenceTranslation Grid 15-12. For example, Object 2 17-4 is associated withTranslation Grid Node 2,6 17-7. To improve the accuracy of thetranslation process, the Object Origin Distance can be computed for eachobject along the X and Y axis. The Object Origin Distance along the Xaxis is the distance of the top left corner of the Object from theassociated Translation Grid Node, computed along the X axis, as apercentage of the Translation Grid Pitch Width Reference Client 15-14.The Object Origin Distance along the Y axis is the distance of the topleft corner of the Object from the associated Translation Grid Node,computed along the Y axis, as a percentage of the Translation Grid PitchHeight Reference Client 15-13. The Reference Fill Score 17-8 for theReference Client Page User Interface is computed as the percentage ofthe Reference Translation Grid which is not covered by any Object,except for the Body Area Background. The Object 1 17-2, Object 3 17-3,Object 5 17-6 are also placed and also illustrated

In order to translate the Reference Client Page User Interface 15-11 andgenerate a corresponding Page User Interface 13-1 for a first ClientDevice 1 1-2, the top left corner of each Object that is displayed inthe Reference Client Page User Interface 15-11 is placed on the Client 1Translation Grid 16-10, on the Translation Grid Node corresponding tothe Translation Grid Node associated with the top left corner of theObject in the Reference Translation Grid 15-12. In order to improveaccuracy, the position of the top left corner of the Object in theClient 1 Translation Grid 16-10 can be adjusted using the Object OriginDistance, using the same percentages computed in the ReferenceTranslation Grid 15-12. Then, the size of the Object is scaledproportionally based on the ratio of the Reference Screen Size 16-3 andClient 1 Screen Size 16-11. The Objects are then adjusted using Client 1Object Formatting Translation Rules 16-14, Client 1 Text FormattingTranslation Rules 16-13 and Client 1 Look and Feel Translation Rules16-17.

FIG. 18 shows the details of the process used by the User InterfaceTranslator 11-2 to perform the translation of each Reference Client PageUser Interface 15-11 comprised in the Reference Client Device UserInterface 11-1 and generate the corresponding Page User Interface 13-1for a first Client Device 1 1-2 in the plurality of Client Devices whichthe Application Client is desired to run on. First, “Place TopNavigation Area” 18-1 generates the Top Navigation Area 13-7 (ifpresent) for the corresponding Page User Interface 13-1 for ClientDevice 1 1-2. If the result of “Top Navigation Translation Rules OK?”18-2 is “YES”, the “Place Bottom Navigation Area” 18-3 is executed,otherwise adjustments are made to the generated Top Navigation Area 13-7until the Client 1 Top Navigation Translation Rules 16-15 are satisfied.

“Place Bottom Navigation Area” 18-3 generates the Bottom Navigation Area13-8 (if present) for the corresponding Page User Interface 13-1 forClient Device 1 1-2. If the result of “Bottom Navigation TranslationRules OK?” 18-4 is “YES”, the “Look and Feel Translation Rules OK?” 18-5is executed, otherwise adjustments are made to the generated BottomNavigation Area 13-8 until the Client 1 Bottom Navigation TranslationRules 16-16 are satisfied. The Top Navigation Area 13-7 and BottomNavigation Area 13-8 must be generated separately from the Body Area13-10 because they are governed by the Top Navigation Translation Rules16-15 and Bottom Navigation Translation Rules 16-16, rather than theplacement of the Objects on the Client 1 Translation Grid 16-10, whichapplies to the Body Area 13-10. The “Look and Feel Translation RulesOK?”18-5 checks that the Client 1 Look and Feel Translation Rules 16-17are satisfied. If they are, the process moves to the “Convert ObjectSizes and Resolution” 18-6, otherwise adjustments are made until theClient 1 Look and Feel Translation Rules 16-17 are satisfied. The“Convert Object Sizes and Resolution” 18-6 scales the size of the Objectproportionally based on the ratio of the Reference Screen Size 16-3 andClient 1 Screen Size 16-11. The “Place Objects on Translation Grid” 18-7places the Objects on the Client 1 Translation Grid 16-10. For eachObject, the top left corner is placed on the Client 1 Translation Grid16-10, on the Translation Grid Node corresponding to the TranslationGrid Node associated with the top left corner of the Object in theReference Translation Grid 15-12. In order to improve accuracy, theposition of the top left corner of the Object in the Client 1Translation Grid 16-10 can be adjusted using the Object Origin Distance,using the same percentages computed in the Reference Translation Grid15-12. The “Adjust Objects on Translation Grid” 18-8 then adjusts theObjects by tweaking their sizes to minimize distortion. The Objects arethen adjusted using Client 1 Object Formatting Translation Rules 16-14,Client 1 Text Formatting Translation Rules 16-13 and Client 1 Look andFeel Translation Rules 16-17.

The “Compute Fill Score” 18-9 computes the Client 1 Fill Score as thepercentage of the Reference Translation Grid which is not covered by anyObject, except for the Body Area Background. The “Compute TranslationRatio” 18-10 computes the Translation Ratio for the Page User Interface13-1 as the ratio between the Client 1 Fill Score and the Reference FillScore 17-8. The computed Translation Ratio for the Page User Interface13-1 is compared with a pre-configured Translation Threshold 17-9 in “IsTranslation Ratio <=Translation Threshold?” 18-11. If the computedTranslation Ratio for the Page User Interface 13-1 is smaller or equalthan the Translation Threshold 17-9, the “Translation Completed,Optimal” is reached. The Translation Threshold is configuredempirically. A Translation Ratio equal to 1 is an indication of a“perfect translation,” since the Objects in the Client 1 Page UserInterface maintain the same relative sizes and positions of the Objectsin the corresponding Reference Client Page User Interface 15-11.However, because of the wide variations in the characteristics ofdifferent Client Devices, a “perfect translation” is not alwayspossible. The Translation Threshold is typically configured to a valueabove 1, to allow for some tolerance in the translation process.

If the computed Translation Ratio is larger than the TranslationThreshold 17-9, a Current Iteration Parameter is incremented and the “IsMaximum Iterations Reached?” 18-13 is executed. If the value of theCurrent Iteration Parameter is lower than the value of a pre-configuredMaximum Iteration Parameter, adjustments are made in the Objects and intheir placement in an attempt to improve the translation result.Adjustments are introduced by executing “Apply Text FormattingTranslation Rules” 18-15, “Apply Object Formatting Translation Rules”18-16 and “Compute New Object Sizes and Positions” 18-17, and thenrepeating “Place Objects on Translation Grid” 18-7 and the rest of theprocess. Examples of adjustments that can be made include the following.Tweaks in the size and position of the Objects, according to the Client1 Object Formatting Translation Rules 16-14 and the relationshipsbetween Objects, such relationships including maintain alignment andrelative sizes of Objects. Changes in the Fonts, Font Sizes, Spacingbetween Words, Spacing between Letters, etc., according to the Client 1Text Formatting Translation Rules.

Once the value of the Current Iteration Parameter reaches the value ofthe Maximum Iteration Parameter, the process is terminated and the“Translation Completed, Suboptimal” 18-14 is reached. The “TranslationCompleted, Suboptimal” 18-14 indicates that the translated Page UserInterface may provide a user experience that is in some respectdifferent than the user experience provided by the correspondingReference Client Page User Interface 15-11. If the “TranslationCompleted, Suboptimal” 18-14 is reached for a certain Page UserInterface 13-1 for a first Client Device 1 1-2, the Business Entity maydecide to have a User Interface designer skilled in the art adjust theObjects on the Page User Interface manually.

The process described in FIG. 18 is repeated for all Reference ClientPage User Interfaces 15-11 comprised in the Reference Client Device UserInterface 11-1.

Finally, it is understood that the above descriptions are onlyillustrative of the principle of the current invention. Variousalterations, improvements, and modifications will occur and are intendedto be suggested hereby, and are within the spirit and scope of theinvention. This invention can, however, be embodied in many differentforms and should not be construed as limited to the embodiments setforth herein. Rather, these embodiments are provided so that thedisclosure will be thorough and complete, and will fully convey thescope of the invention to those skilled in the arts. It is understoodthat the various embodiments of the invention, although different, arenot mutually exclusive. In accordance with these principles, thoseskilled in the art can devise numerous modifications without departingfrom the spirit and scope of the invention. For example, In addition, anetwork and a portable system can exchange information wirelessly byusing communication techniques such as Time Division Multiple Access(TDMA), Frequency Division Multiple Access (FDMA), Code DivisionMultiple Access (CDMA), Orthogonal Frequency Division Multiplexing(OFDM), Ultra Wide Band (UWB), Wi-Fi, WiGig, Bluetooth, etc. The networkcan comprise the phone network, IP (Internet protocol) network, LocalArea Network (LAN), ad hoc networks, local routers and even otherportable systems. In addition, the term “Mobile Client Device” can beused for mobile devices such as cellphone, tablets, etc. “Non-MobileClient Device” can be used for non-mobile devices such as desktops.“Cloud Client Device” can be used for the device formed in the Cloud. Atother instants the term “Client Device” can imply either the “MobileClient Device,” “Non-Mobile Client Device” or “Cloud Client Device.”

1. A method of automatically generating content translation for a mobiledevice comprising: superimposing a reference translation grid on a userinterface of a reference mobile device, wherein the user interface ofthe reference mobile device comprises one or more objects; computing areference fill score based on a covered portion of the referencetranslation grid occupied by the one or more objects; selecting a clientmobile device; superimposing a client translation grid on a userinterface of the selected client mobile device; placing the one or moreobjects of the reference mobile device on the client translation grid;computing a client fill score based on the covered portion of the clienttranslation grid occupied by the one or more objects of the referencemobile device on the client translation grid; computing a translationratio as the ratio of the client fill score and the reference fillscore; and comparing the computed translation ratio to a translationthreshold.
 2. The method of claim 1, wherein the client fill score is apercentage of the client translation grid that is not covered by any ofthe one or more objects.
 3. The method of claim 1, wherein the referencefill score is a percentage of the reference translation grid that is notcovered by any of the one or more objects.
 4. The method of claim 1,wherein if the computed translation ratio is greater than thetranslation threshold an adjustment is made to the one or more objectsin the client translation grid.
 5. The method of claim 4, wherein theadjustment comprises a change in size and a placement in the clienttranslation grid.
 6. The method of claim 1, wherein the referencetranslation grid and the client translation grid each comprise one ormore rows and one or more columns.
 7. The method of claim 6, wherein thereference translation grid contains a same number of rows and columns asthe client translation grid.
 8. The method of claim 1, wherein thereference mobile device comprises a first operating system and theselected client mobile device comprises a second operating system. 9.The method of claim 1, wherein the reference mobile device comprises ascreen with a first resolution and the selected client mobile devicecomprises a screen with a second resolution.
 10. A system for generatingcontent translation for a mobile device comprising: a reference mobiledevice comprising a display and a reference user interface, wherein thereference user interface comprises one or more objects and asuperimposed reference translation grid; a user interface translatorconfigured to compute a reference fill score based on a covered portionof the superimposed reference translation grid occupied by the one ormore objects; a client mobile device comprising a display and a clientuser interface, wherein the client user interface comprises the one ormore objects and a superimposed client translation grid; and the userinterface translator further configured to compute a client fill scorebased on a covered portion of the superimposed client translation gridoccupied by the one or more objects, and to compute a translation ratioas a ratio of the client fill score and the reference fill score,wherein the computed translation ratio is compared to a translationthreshold.
 11. The system of claim 10, wherein the user interfacetranslator is configured to compute the client fill score as apercentage of the superimposed client translation grid that is notcovered by any of the one or more objects.
 12. The system of claim 10,wherein the user interface translator is configured to computer thereference fill score as a percentage of the superimposed referencetranslation grid that is not covered by any of the one or more objects.13. The system of claim 10, wherein the user interface translator isconfigured to determine if the computed translation ratio is greaterthan the translation threshold, wherein an adjustment is made to the oneor more objects in the superimposed client translation grid.
 14. Thesystem of claim 13, wherein the user interface translator is configuredto make the adjustment comprising a change in size and a placement inthe superimposed client translation grid.
 15. The system of claim 10,wherein the user interface translator is configured to generate thesuperimposed reference translation grid and the superimposed clienttranslation grid where each comprises one or more rows and one or morecolumns.
 16. The system of claim 15, wherein the user interfacetranslator is configured to generate the superimposed referencetranslation grid that contains a same number of rows and columns as thesuperimposed client translation grid.
 17. The system of claim 10,wherein the user interface translator is cloud based.
 18. The system ofclaim 10, wherein the reference mobile device comprises a firstoperating system and the client mobile device comprises a secondoperating system.
 19. The system of claim 10, wherein the referencemobile device comprises a screen with a first resolution and the clientmobile device comprises a screen with a second resolution.
 20. Thesystem of claim 10, wherein the reference mobile device comprises ascreen with a first aspect ratio and the client mobile device comprisesa screen with a second aspect ratio.